DE102018217774A1 - Radar and light emitting device for vehicles for emitting light and radar radiation as well as method and use - Google Patents

Abstract

So far, separate components have been used in many cases when emitting light and radar radiation. There is a need for a combined device which can combine the advantages of light and radar radiation even with device-related synergies. A radar and light emission arrangement (10) is provided for emitting light and radar radiation and for detecting at least reflected radar radiation, comprising: a headlight (1) with a light-transparent headlight cover (4) and a light source (2) and a light reflector (3) ; a radar module (11) with a radar antenna unit (12) arranged behind the headlight cover and integrated into the headlight; wherein the radar and light emission arrangement (10) has at least one radar radiation shaping device (13, 14), in particular a frequency-selective radar radiation shaping device, comprising a radar radiation shaping device integrated in the headlight cover. In this way, the application of the radar technology integrated in the headlight can be further optimized. The invention further relates to a method and a use for such a radar and light emission arrangement.

Description

TECHNICAL AREA

The present invention relates to a radar and light emission arrangement, in particular for vehicles, set up for emitting light and radar radiation and set up for detecting driving situations in a detection area by means of the radar radiation, in particular for the purpose of assisting in the navigation of the vehicle. In particular, the invention also relates to a method for emitting light and radar radiation and for detecting at least reflected radar radiation. Last but not least, the present invention also relates to the use of the radar and light emission arrangement. In particular, the invention relates to a device and a method according to the preamble of the respective independent claim.

BACKGROUND OF THE INVENTION

In the case of vehicle headlights in particular, attempts are already being made to create a combined device with integrated functionality both for lighting and for radar radiation with high practical suitability. Space requirements and robustness are important requirements when designing headlights, especially for vehicles. A combined application of light and radar radiation has proven to be particularly advantageous when detecting relative positions in passenger traffic. Driver assistance systems, such as adaptive distance control, lane departure warning systems and emergency braking systems, are used today in many vehicles across all classes, especially in passenger cars. However, such systems also offer advantages in the shipping or aviation industry and are already being used or at least tested. Radar technology is particularly important for distance measurements. However, it is questionable at which position on the vehicle the radar technology should be arranged in a sensible manner and possibly should interact with other detection components. The conventional integration of radar technology in the bumper of a road vehicle carries a high risk of damage, especially in the event of small impacts or only slight contact of the vehicle with the surroundings. In the case of integration in the radiator area, in turn, compromises for the vehicle design have to be accepted. Another challenge when integrating radar components in vehicles (especially cars), especially in the front, is to compensate for damping of the transmit and receive signals on the individual layers of material (especially on the bumper) and on the paint layers. Artifacts and echo images in the radar signal usually have to be eliminated. In other words, depending on the application, the exact evaluation of radar signals is not trivial.

As a result, attempts have recently been made to integrate the radar technology into the headlights of a vehicle.

US 2008/0158045 A1 describes a vehicle headlight with a light unit and with a radar unit integrated in the headlight, which comprises an antenna and a control unit, the control unit being arranged below the light unit and below a light reflector and being fastened to a bottom wall of the lamp housing, and wherein the antenna on Light reflector is attached or is arranged in an area spanned or spanned by the light reflector, in particular in order to be able to ensure good radiation efficiency.

US 2011/0279304 A1 describes a vehicle headlight with a light unit and a light reflector and with a projection lens and with a radar unit integrated in the headlight, which comprises an antenna and a control unit, the control unit and the antenna being arranged between the light unit and the projection lens, the antenna being arranged in this way is that an optical interaction of the radar radiation with the projection lens is ensured, which projection lens is also arranged in optical interaction with the light unit and the light reflector.

On the basis of this prior art, there is interest in an arrangement and a method for combined light and radar radiation, with which further advantages can be achieved and the benefits for road users can be further increased.

SUMMARY OF THE INVENTION

The object is to provide a device and a method with which the radiation of light and radar radiation and the detection of reflected radiation by headlights can be optimized, in particular for vehicles or motor vehicles. In particular, the task is to implement the emission of light and radar radiation and the detection of reflected radiation in such a way that both the light and the radar radiation are used in combination with one another in an integrated design in a common device for the navigation of a vehicle can, especially with advantageous side effects with regard to structural design and space requirements or also with regard to the possible range of applications or also with regard to high reliability of the technology.

This object is achieved by a radar and light emission arrangement according to claim 1 and by a method according to the respective subordinate method claim. Advantageous developments of the invention are explained in the respective subclaims. The features of the exemplary embodiments described below can be combined with one another, unless this is explicitly denied.

A radar and light emission arrangement is provided, in particular for vehicles, set up for emitting light and radar radiation and set up for detecting at least reflected radar radiation, comprising: a headlamp with a light-transparent headlamp cover and one behind the headlamp cover, i.e. in the radiation direction in front of the headlamp cover Light source and a light reflector; and with a radar module with a radar antenna unit which is arranged behind the headlight cover and is integrated into the headlight. It is proposed according to the invention that the radar and light emission arrangement has at least one radar radiation shaping device, in particular a frequency-selective radar radiation shaping device, in particular comprising a radar radiation shaping device integrated in the headlight cover. This not only provides an advantageous relative arrangement, but also high variability with regard to the use of radar radiation, and in particular also a decoupling from the use of light radiation. As a result, the radar technology can be optimized with advantageous integration into the headlamp with high degrees of freedom.

The radar module can be arranged in particular in the direction of radiation between the headlight cover and the light source, the headlight cover having a frequency-selective radar transmission structure. It has been shown that the radar module is arranged as far forward as possible in the emission direction x is advantageous, particularly close to the headlight cover, especially in an overlapping arrangement with the headlight cover.

In contrast to previously tested technologies, the arrangement according to the invention enables the advantages such as e.g. Protection and integrated design within the headlamp can also be used for radar technology without having to accept any noticeable restrictions in terms of the lighting function.

In the arrangement according to the invention, the headlight cover can also be used as a radome or antenna dome. The headlight cover can in particular be made of plastics, such as Polycarbonate, or glass exist. The headlight cover or its material is (per se) transparent to light and radar radiation (RF waves).

Radar is to be understood as one of the already available or established technologies for emitting and detecting electromagnetic waves in the radio frequency range, ie radar in the general sense of "Radio Detection And Ranging" or "Radio Direction And Ranging". This radar technology can e.g. Include laser radar and / or millimeter wave radar.

According to one exemplary embodiment, the radar and light emission arrangement comprises at least one component from the following group, which each interacts and / or filters the radiation and / or filtering relation to the radar module in the radiation direction between the headlamp cover in interaction with radar radiation or in optical relation or in relation to the radar radiation and the light source or arranged directly on the headlight cover (inside and / or outside): radar reflector, at least one frequency-selective radar transmission structure. This also provides advantages in relation to the relative arrangement of the components in the headlight to one another.

In the event that a projection lens is to be provided in the headlight (projection method instead of reflector method with light source), the arrangement of the radar module and one / of the radar reflector can be described analogously, that is to say with the projection lens in the position of the light source described here. In other words, a reference to the light source can also be interpreted as a reference to a projection lens.

The headlight cover can serve as the main radome for the radar system. The headlight cover can e.g. be made of polycarbonate or glass. The headlight cover is preferably transparent to light and also to HF waves. In order to minimize reflections, in particular in the frequency range from 76 to 81 GHz, the thickness of the headlight cover can be chosen as an integral multiple of half the wavelength.

Advantageous configurations relating to the arrangement of the radar module are described below.

According to one exemplary embodiment, the radar module is arranged outside (in particular below or behind) a light cone emitted by the light source. In other words: that Radar module can be arranged outside the light propagation area, that is laterally spaced from the optical axis of the light source (s). According to one embodiment, the radar module is arranged below a tangential plane or horizontal plane delimiting the light reflector downwards. According to one exemplary embodiment, the radar module is arranged outside (in particular below) an optical axis or an axis corresponding to the main orientation of the light reflector or the light source. This also makes it possible to optimize the relative arrangement to one another. Optionally, a / the radar module can be arranged behind the light source (s), in particular when the optical axis of the radar module is oriented essentially parallel to (or in register with) the central longitudinal axis of a light cone of the light sources. A radar radiation shaping device can be arranged between the radar module and the light sources.

Radar emitters and receivers are not arranged in the beam path, but outside of it, especially below it. By reflecting the radar radiation at the reflector and by deflecting the radar radiation in the range from 60 to 120 °, in particular 90 °, with an advantageous relative arrangement of the individual components, the radar radiation can be deflected in the direction of the vehicle front and at the same time beam shaping can be ensured.

In particular, the radar module or a radar emitter and receiver can be aligned vertically upwards. A transparent reflector (in particular a so-called Fresnel reflect array) with a coating can be arranged in front of it. The antennas used in the radar module are preferably planar antennas (e.g. patch / slot). The antennas can preferably be integrated into the radar module via transmission lines (e.g. microstrip lines) without additional adapters. The antennas can consist of several individual antennas or array antennas, in particular in a two-dimensional arrangement.

The reflector is transparent to the light from the light source and only reflects the radar radiation and directs it forward through the cover. The reflector forms the radar radiation into a desired lobe or surface shape.

The cover can be coated in order to provide the frequency-selective transmission structure and to only transmit radar radiation in a certain band range.

According to one embodiment, the radar module is arranged in an area below the headlight cover in an overlapping arrangement with the headlight cover. This also provides an advantageous decoupling from the lighting function. In addition, the headlamp cover or its geometry can also be used as a radome, so that good efficiency and quality of evaluation can be ensured.
According to one exemplary embodiment, the radar module is arranged on the bottom of a housing of the headlight, in particular in a mechanical coupling to the bottom. This also favors decoupling from the lighting function.
According to one exemplary embodiment, an intermediate level with a radiation-effective cover is provided on the radar module or directly above the radar module, with the cover in particular in the form of a plastic, in particular polycarbonate layer, in particular with a one-sided, at least light-opaque coating. This also provides further degrees of freedom when setting the radiation characteristic. In particular, an advantageous arrangement for the radar module can be implemented largely independently of the lighting function, in particular with a cover designed as a heat shield. In other words, the cover can be heat-insulating or heat-shielding or at least have a corresponding heat-shielding layer.

According to one embodiment, the at least one radar radiation shaping device is arranged in a radiation direction of the radar radiation.

According to one exemplary embodiment, the at least one radar radiation-shaping device is arranged in the direction of reflection of the radar radiation.

According to one embodiment, the at least one radar radiation shaping device is flat, in particular planar or curved.

According to one exemplary embodiment, the at least one radar radiation-shaping device is frequency-selective, in particular in that the radar radiation-shaping device comprises a frequency-selective radar transmission structure. The radar radiation shaping device is in particular frequency-selective in that the radar radiation shaping device has dimensions which are matched to the wavelength of the radar radiation emitted (frequencies).

According to one exemplary embodiment, the at least one radar radiation-shaping device is arranged in the radiation direction of the light source.

According to one exemplary embodiment, at least two radar radiation-shaping regions, each with an individual radar radiation-shaping function, are provided on the at least one radar radiation-shaping device. This also makes it possible to individually influence a first part of the radar radiation and to influence a second part of the radar radiation individually in a different way than the first part, in particular for the purpose of optimized detection in near and far areas and / or in front and side areas.

According to one exemplary embodiment, the at least two radar radiation-shaping regions are arranged / formed in the same radar radiation-shaping device. This also enables extensive function integration.

In particular, the different radar radiation-shaping regions can comprise at least one electrically conductive region and at least one electrically non-conductive region.

The radar radiation forms in particular a radiation front, which can be reflected by means of the arrangement according to the invention, in particular in the electrically conductive areas, so that an interference pattern can be predefined.

In the following, advantageous configurations regarding the alignment of the radar module or regarding the arrangement of the radar module relative to further components are described.

According to one embodiment, an optical axis of the radar module or the radar antenna unit is oriented at least approximately vertically upwards (perpendicularly) in the intended arrangement of the headlight. According to one embodiment, the optical axis of the radar module or the radar antenna unit is directed towards a radar reflector integrated behind the headlight cover in the headlight and in the direction of radiation behind the light source, the optical axis of the radar module being aligned with the radar reflector in such a way that the radar module is at the bottom of the headlight can be arranged. This also enables local decoupling of the radar module from the light propagation path.

The relative placement of the integrated antenna and radar module remains comparatively flexible, especially since it is sealed off from the outside of the headlamp. The relative placement described here has proven to be particularly advantageous.

Advantageous configurations relating to the radar antenna unit are described below.

According to one exemplary embodiment, a / the radar antenna unit is arranged on / on an upper side of the radar module. This relative arrangement is also advantageous with regard to decoupling from the light propagation path.
According to one embodiment, the radar antenna unit is designed as a planar antenna (in particular in the form of a patch and / or slot antenna). This facilitates integration, particularly in the arrangement according to the invention.
According to one exemplary embodiment, the radar antenna unit has a plurality of individual antennas or antenna arrays in a two-dimensional arrangement. This favors a high degree of variability when setting the radiation characteristic.
According to one embodiment, the radar antenna unit is integrated into the radar module by means of microstrip lines without additional adapters. This also facilitates integration.

The radar module can in particular contain all those RF front ends and electronic components and circuits that can be produced on planar dielectric substrates. The antennas are all advantageously located at the foot (bottom) of the headlight housing in the vicinity of the headlight cover, in particular in an arrangement at least partially overlapped by the headlight cover.

A radiation-effective cover is arranged in an intermediate plane between the radar reflector and the radar module, in particular in a direction / plane at least approximately orthogonally to the optical axis of the radar module, in particular in order to optically isolate the radar module. The cover advantageously consists of flat, thin plastic (in particular of polycarbonate), the plastic being able to be coated dark on one side. The cover is preferably arranged and set up to act as a heat shield for electronic components. This arrangement of the cover also provides a slim design.

Advantageous configurations relating to a radar reflector of the arrangement according to the invention are described below.

According to one exemplary embodiment, the radar and light emission arrangement has a radar reflector arranged behind the headlight cover and integrated in the headlight, the radar module being arranged below the radar reflector. According to one exemplary embodiment, the radar reflector is arranged in an arrangement that overlaps or overlaps the radar module, in particular in such a way that the radar module in plan view against the optical axis of the radar module only from the radar reflector or together with the headlight cover is completely covered. According to one embodiment, the radar reflector is arranged at least approximately in the same longitudinal position together with the radar module, in particular completely overlapped or covered by the headlight cover, in particular in a last third of the longitudinal extent of the radar and light emission arrangement in the direction of radiation up to the headlight cover. According to one embodiment, the radar reflector is arranged below an optical axis or below an axis corresponding to the main orientation of the light reflector or the light source. This also provides an advantageous relative arrangement of the components to one another.

In other words: in the arrangement according to the invention, a radar reflector and optionally also a high-frequency lens in the area of the headlight cover can adapt the radar radiation in a particularly flexible manner (that is, with high variability) according to the respective situation, in particular largely decoupled from the lighting function. If the radar system is integrated into a motor vehicle headlight, its radar signal can be tailored to the desired detection area, in particular by means of at least one structured conductive layer / surface (radar transmission structure, in particular with patterns in the sense of functional small structures) in the headlight cover. In addition, the headlight of a motor vehicle can also perform a protective function for radar technology, in particular thanks to the headlight cover.

According to one exemplary embodiment, the beam path of the radar radiation is deflected by means of the radar reflector in the range from 70 to 110 °, in particular in the range of 90 °, in particular at least approximately in the direction of radiation of the radar and light radiation arrangement. This also provides advantages in terms of the arrangement of the components relative to one another.

According to one embodiment, the radar reflector has a two-dimensional extension. This can also make the structure as simple and robust as possible.

According to one exemplary embodiment, the radar reflector, in particular the inside thereof, is at an inclination in the range from 35 to 60 °, in particular 40 to 50 °, relative to the direction of radiation x or arranged relative to the horizontal, at least in sections. According to one embodiment, the radar reflector is arranged relative to the headlight cover such that the radar reflector and the headlight cover form a roof structure covering the radar module with the geometry of a gable roof with two oppositely inclined surfaces, in particular with an included angle in the range from 45 to 90 °. This also provides an advantageous relative arrangement in each case and can facilitate the functional integration.

According to one embodiment, the arrangement and / or orientation of the radar reflector is adjustable by a motor. This also enables great variability and can expand the range of functions.
According to one embodiment, the radar reflector has a three-dimensional extent at least in sections and is designed to also laterally reflect radar radiation. Last but not least, this also extends the functionality. In particular, even small installation space can be ensured high / wide functionality with simple means. According to one exemplary embodiment, the radar reflector is formed from a plurality of two-dimensional elements and, as a result, has a two-dimensional extension for each element or two-dimensional or three-dimensional extension with respect to all elements. This also provides a high degree of variability.
According to one exemplary embodiment, the radar reflector is designed as a Fresnel reflector, both sides of the radar reflector having a frequency-selective radar transmission structure, and the radar reflector being designed to focus and / or collimate the radar radiation. This enables a very targeted influence on the radiation characteristics.

According to one exemplary embodiment, the radar reflector consists of substrate material which is transparent to light and radar radiation and has a device which forms radar radiation, in particular in the form of a coating or as an electrically conductive surface, in particular with a frequency-selective radar transmission structure. This can also ensure a particularly simple and robust construction. The electrically conductive layer or surface, regardless of its arrangement, can be formed in particular from copper.
According to one exemplary embodiment, the radar reflector has a radar radiation-shaping device and is arranged relative to the headlamp cover in such a way that the radar radiation from the radar module to the outside of the headlamp cover passes / shines through the respective frequency-selective radar transmission structure at least twice. This also provides a high degree of variability. In other words, the radar radiation can be conducted via a first filter provided by the radar reflector (first radar transmission structure) and, after deflection, also via a second filter provided by the headlight cover (second or further radar transmission structure).

According to one embodiment, the radar reflector is formed from individual reflector elements, each of which is rectangular or triangular, in particular with the same side length. This provides a kind of modular structure for high variability, especially with a simple basic structure for each individual reflector element.

According to one embodiment, the radar reflector has a light-transparent, electrically conductive oxide layer or electrically conductive surface on at least one of its surfaces. This provides good reflectivity. The radar transmission structure can be provided at least partially by means of the oxide layer. This type of integration of the radar transmission structure provides not only a comparatively high variability (key word: influencing the type of radiation propagation) but also advantages in terms of space requirements.

According to one exemplary embodiment, the radar reflector is light-transparent (transparent to light or visible radiation) and radar radiation-opaque (reflective for radar or RF waves). This also provides good variability in arrangement relative to the light source.
According to one exemplary embodiment, the radar reflector is set up to shape the radar radiation, in particular in the form of a club or surface. This extends the application possibilities.

The radar reflector is set up to redirect and / or collimate the incoming RF waves. By using a reflector instead of a lens, there is no need to adjust the RF wave impedance.

• Planarer Reflektor: Der Reflektor ist eingerichtet, die Strahlung der Antenne gemäß dem Snell'schen Gesetz zu reflektieren.
• Geformter Reflektor: Die Strahlung wird in Abhängigkeit der 3D-Form des Reflektors reflektiert und gestreut, insbesondere auch in lateraler Richtung. Eine Erhöhung oder Verminderung der EM-Wellenintensität (Richtwirkung des Abstrahlverhaltens) kann durch geeignete Formgebung des Reflektors eingestellt bzw. vorgegeben werden.
• Fresnel-Reflektor: Die Strahlung wird kollimiert und/oder fokussiert. Der Reflektor kollimiert die Welle oder stellt die HF-Wellenkomponenten phasenrichtig ein. Insbesondere ist der Reflektor eingerichtet, sphärische Wellen in planare Wellen umzuwandeln. Vorteilhafter Weise beträgt dabei die Dicke eines Substrats des Reflektors ein ungerades Vielfaches des Viertels der Wellenlänge. Dies begünstigt eine Wandlung in planare Wellen.

The radar reflector can be referred to as an intermediate structure that is selective for radar radiation between the radar module or a radar antenna and the RF wave in space. The reflector can have the following shapes:

• Planar reflector: The reflector is set up to reflect the radiation of the antenna in accordance with Snell's law.
• Shaped reflector: The radiation is reflected and scattered depending on the 3D shape of the reflector, especially in the lateral direction. An increase or decrease in the EM wave intensity (directivity of the radiation behavior) can be set or specified by suitable shaping of the reflector.
• Fresnel reflector: The radiation is collimated and / or focused. The reflector collimates the wave or adjusts the RF wave components in phase. In particular, the reflector is set up to convert spherical waves into planar waves. The thickness of a substrate of the reflector is advantageously an odd multiple of the quarter of the wavelength. This favors conversion into planar waves.

The radar reflector can consist of substrate material which is transparent not only for the light but also for the RF waves. In particular, the reflectivity can be set or predefined by coating one or two sides of the substrate with a very thin, transparent, conductive oxide (TCO).

In the Fresnel reflector, two surfaces are preferably provided which are coated by means of the TCO. The planar or shaped reflector is preferably only provided for a TCO-coated surface.

The radar reflector is preferably arranged in the vicinity of the headlight housing, clearly in front of the light source. The arrangement is preferably between the headlight cover and the projection lens (in the case of headlights with a projection method) or between the headlight cover and the light source (in the case of headlights with the reflector method).

The radar reflector is inclined or aligned in such a way that the transmitting RF waves can properly illuminate the intended objects and that the receiving waves can be focused on the receiving antenna.

Advantageous embodiments relating to the at least one radar radiation shaping device with frequency-selective radar transmission structure are described below.

According to one exemplary embodiment, at least one or the respective radar radiation-shaping device with frequency-selective radar transmission structure has, at least in sections, a periodic arrangement of structural patterns, with the structural patterns in particular in a concentric arrangement. This also makes it possible in a particularly flexible manner to design and optimize the arrangement according to the invention with regard to individual applications.
According to one exemplary embodiment, the radar radiation-shaping device is designed with a frequency-selective radar transmission structure as a coating or as a film or as an electrically conductive surface. This can further simplify the construction. In particular, a coating can also be provided as a supplement to integrated patterns or structures.
According to one embodiment, the headlight cover forms a substrate for the Radar radiation shaping device or for the frequency-selective radar transmission structure. This provides a particularly robust structure, in particular in the form of a basic module, which can be used for various applications and further adapted. According to one embodiment, the radar radiation shaping device has a conductive part in the form of a light-transparent, electrically conductive oxide layer. This also enables the reflection properties to be optimized.

The radar transmission structure can have a periodic arrangement of patterns (keyword: unit cell), which are set up to filter over the intended frequency band, e.g. Bandpass filter at 76 GHz to 81 GHz.

• unerwünschte HF-Wellen außerhalb des vorgesehenen Bandes (z.B. 76 bis 81 GHz) filtern; und die Strahlungscharakteristik der erwünschten HF-Wellen vorgeben (insbesondere Ausstrahlungs-Richtung, Art und Weise und Umfang einer Kollimation und/oder einer Streuung).

The radar transmission structure can also be integrated into the headlight cover, the headlight cover serving as a substrate for the radar transmission structure. A conductive part of the radar transmission structure preferably consists of ultra-thin, transparent, conductive oxide or a corresponding oxide layer (TCO). The radar transmission structure can perform at least two functions, regardless of the arrangement on the reflector and / or on the headlight cover:

• filter unwanted RF waves outside the intended band (eg 76 to 81 GHz); and specify the radiation characteristics of the desired RF waves (in particular the direction of emission, the type and extent of collimation and / or scattering).

The radar transmission structure can have different configurations, which are not limited to simple geometries (e.g. complementary loops, crosses, stripes), but can e.g. also contain more complex meander-based slots (especially for the bandpass), in particular to reduce the size of the unit cell and to achieve better angular stability.

The transmission structures can be set up for bundling, deflecting and / or filtering the radar waves, so that different scanning ranges, ranges and deflection angles can be realized.

Advantageous configurations relating to the headlight cover are described below.

According to one exemplary embodiment, the headlight cover consists of material which is transparent to light and radar radiation, in particular of substrate material for the frequency-selective radar transmission structure in the form of an integrated coating. This enables an even more extensive integration of functions, especially with a robust design.
According to one embodiment, the headlamp cover has a thickness corresponding to an integral multiple of half the wavelength of the radar radiation emitted. This also makes it possible to optimize the transmission properties.
According to one embodiment, a frequency-selective radar transmission structure is provided on both sides (inside and outside) of the headlight cover. This favors a particularly targeted influence on the radiation characteristics.
According to one embodiment, the radar and light emission arrangement is designed without a projection lens, in that the radar beam path runs from the radar module via the radar reflector and the headlight cover and by the light propagation path from the light source and the light reflector runs directly over the headlight cover, that is to say in each case without further intermediate optical or radiation-effective components. In other words, the entire arrangement is without a projection lens, that is to say without a lens. Last but not least, this also provides a simple, compact, robust construction.

According to one exemplary embodiment, the headlight cover is arranged relative to the radar module in such a way that the headlight cover forms a radome for the radar module. This can further optimize the functional integration in the headlamp, particularly with regard to the sensitivity and / or accuracy of the evaluation.

An exemplary functional description is provided below.

By means of the arrangement according to the invention, a selective scanning of the surrounding situation can be implemented via a transmission and reception array, in which not only the front area (frontal) but optionally also the side area (lateral) can be covered. The number of sensor systems required can also be reduced in the headlight. A significantly improved resolution can also be realized. In particular in the case of laser-based structuring of thin layers, a desired radiation shaping can be implemented in a flexible manner, so that the adaptation of the radar properties to the respective headlight type and to the desired scanning space in the near and far field can be optimized.

It has been shown that transparent plastic substrates can be coated with transparent but electrically conductive layers, which layers can subsequently be removed locally. For the manufacture of structures that can be individually designed for a particular application In particular, a laser process can also be used for thin-film removal, with the advantage of largely residue-free removal without damage to the substrate and without optical disadvantages.

The radar transmission structure can optionally be applied in a lithographic manner and / or by means of masked coating and printing.

• einem Scheinwerfer mit einer lichttransparenten Scheinwerferabdeckung und einer hinter der Scheinwerferabdeckung angeordneten Lichtquelle und einem Lichtreflektor;
• einem hinter der Scheinwerferabdeckung integriert in den Scheinwerfer angeordneten Radarmodul mit einer Radarantenneneinheit; wobei das Radarmodul in Ausstrahlungsrichtung x zwischen der Scheinwerferabdeckung und der Lichtquelle angeordnet ist, wobei die Scheinwerferabdeckung eine frequenzselektive Radardurchlassstruktur aufweist, wobei das Radarmodul unterhalb einer optischen Achse oder einer Achse entsprechend der Haupt-Ausrichtung des Lichtreflektors oder der Lichtquelle angeordnet ist, wobei das Radarmodul in einem Bereich unterhalb von der Scheinwerferabdeckung in überlappender Anordnung mit der Scheinwerferabdeckung angeordnet ist, wobei eine optische Achse des Radarmoduls oder der Radarantenneneinheit in bestimmungsgemäßer Anordnung des Scheinwerfers zumindest annähernd nach vertikal oben ausgerichtet ist, wobei die Radar- und Lichtausstrahlungsanordnung einen hinter der Scheinwerferabdeckung integriert in den Scheinwerfer angeordneten Radarreflektor aufweist, wobei das Radarmodul unterhalb vom Radarreflektor angeordnet ist, wobei der Radarreflektor unterhalb der optischen Achse oder einer Achse entsprechend der Haupt-Ausrichtung des Lichtreflektors oder der Lichtquelle angeordnet ist, wobei ein/der Strahlweg der Radarstrahlung mittels des Radarreflektors im Bereich von 70 bis 110°, insbesondere im Bereich von 90° umgelenkt wird, insbesondere zumindest annähernd in die Ausstrahlungsrichtung x der Radar- und Lichtausstrahlungsanordnung ausgerichtet wird, und wobei der Radarreflektor, insbesondere dessen Innenseite, mit einer Neigung im Bereich von 35 bis 60°, insbesondere 40 bis 50°, relativ zur Ausstrahlungsrichtung x oder relativ zur Horizontalen angeordnet ist, zumindest abschnittsweise. Hierdurch ergeben sich zahlreiche zuvor genannte Vorteile.

The aforementioned object is in particular also achieved by a radar and light emission arrangement, in particular for vehicles, set up for emitting light and radar radiation and set up for detecting at least reflected radar radiation, with:

• a headlamp with a light-transparent headlamp cover and a light source arranged behind the headlamp cover and a light reflector;
• a radar module arranged behind the headlight cover and integrated into the headlight with a radar antenna unit; the radar module in the radiation direction x is arranged between the headlamp cover and the light source, the headlamp cover having a frequency-selective radar transmission structure, the radar module being arranged below an optical axis or an axis corresponding to the main orientation of the light reflector or the light source, the radar module being in a region below the headlamp cover is arranged in an overlapping arrangement with the headlight cover, wherein an optical axis of the radar module or the radar antenna unit is oriented at least approximately vertically upwards in the intended arrangement of the headlight, the radar and light emission arrangement having a radar reflector integrated behind the headlight cover, wherein the radar module is arranged below the radar reflector, the radar reflector below the optical axis or an axis corresponding to the main orientation of the light reflector tors or the light source is arranged, a / the beam path of the radar radiation being deflected by the radar reflector in the range from 70 to 110 °, in particular in the range of 90 °, in particular at least approximately in the direction of emission x the radar and light emission arrangement is aligned, and wherein the radar reflector, in particular the inside thereof, has an inclination in the range from 35 to 60 °, in particular 40 to 50 °, relative to the direction of emission x or is arranged relative to the horizontal, at least in sections. This results in numerous advantages mentioned above.

The aforementioned object is also achieved by using a radar and light emission arrangement, in particular a previously described radar and light emission arrangement, for emitting light and for frequency-selective emission of radar radiation and for specifying a radar detection range by means of at least one, in particular by means of at least two, radar radiation shaping devices Devices, in particular frequency-selective radar transmission structures, which devices are / are provided at least in or on at least one side of a light-transparent headlight cover of the radar and light-emitting arrangement, in particular in the beam path starting from a radar module in a row in at least two positions comprising a position outside the light cone Light source (for example on a radar reflector arranged above the radar module), in particular in a headlight of a vehicle, in particular in a headlight s automobile, a radar module of the radar and light emission arrangement being arranged outside a light cone emitted by the light source, in particular below the at least one, in particular below the at least two radar radiation-shaping devices, with an upward, in particular at least approximately orthogonal to the optical axis of one Light source of the headlight, aligned optical axis of the radar module. This results in the aforementioned advantages. The vehicle can be an automobile (motor vehicle for the road) or an aircraft or a watercraft.

The aforementioned object is also achieved by a radar and light emission arrangement for vehicles and set up to emit light and radar radiation and set up to detect at least reflected radar radiation, with a headlight with a light-transparent headlight cover and a light source arranged behind the headlight cover and a light reflector, and with a radar module integrated behind the headlight cover in the headlight with a radar antenna unit, in particular by means of a radar and light emission arrangement described above, produced by forming at least one radar radiation shaping device, in particular in the form of a frequency-selective radar transmission structure, at least also on or in the (optionally as Headlight cover used / serving), the radar radiation shaping device being a conductive part in the form of has light-transparent, electrically conductive oxide layer or is at least partially formed thereby, and wherein a structural pattern is introduced into the radar radiation shaping device by thin-layer removal, in particular by means of a laser. This results in the aforementioned advantages. It has been shown that structures introduced by means of lasers enable the direction and radiation characteristics of the radar radiation to be controlled, adjusted and specified in a particularly precise manner.

The aforementioned object is also achieved by a method for emitting light and radar radiation and for detecting at least reflected radar radiation in each case by means of a radar and light emitting arrangement, in particular by means of a radar and light emitting arrangement described above, in particular in a vehicle, wherein light from a Light source of a headlamp is emitted by a light-transparent headlamp cover according to the direction of an optical axis of the light source, and wherein radar radiation is emitted by a radar module integrated in the headlamp behind the headlamp cover; wherein the radar radiation from the radar module is emitted in a direction transverse, in particular at least approximately orthogonally, to the optical axis of the light source and via at least one radar radiation shaping device provided at least on or in the headlight cover, in particular in the form of a frequency-selective radar transmission structure, in at least one radiation direction of the radar and the light emission arrangement is deflected, in particular at least approximately parallel to the optical axis of the light source, in particular in the direction of travel of a vehicle aligning the headlight, the radiation characteristic of the radar radiation being predetermined by means of the at least one radar radiation-shaping device. This results in the aforementioned advantages.

According to one embodiment, the method comprises emitting the radar radiation via at least two frequency-selective radar transmission structures, which are arranged in the beam path, starting from the radar module, in a row in at least two positions, the positions comprising: a position at an outside of the light cone of the light source (for example above the Radar module) arranged radar reflector and a position on or in the headlight cover; wherein the optical axis of the radar module is in particular aligned at least approximately orthogonally to the optical axis of a light source of the headlight. This also enables the radiation characteristic to be optimized in a particularly variable or exact manner. The respective radar transmission structure can optionally have a structure pattern with a plurality of different structures. This extends the possibilities of influencing the type of radiation radiation.

According to one embodiment, the method also includes detection of reflected radar radiation, the reflected radar radiation being detected in particular on the opposite beam path. This also extends the range of functions.

According to one embodiment, a structure pattern is introduced into the radar radiation shaping device by thin-layer removal or thin-layer application. This can be done, for example, by laser ablation, by means of a film, by means of a printing, coating or vapor deposition process (sputtering, thermal evaporation and / or electron beam evaporation) and / or by means of lithography.

According to one embodiment, the radar radiation shaping device is produced by means of thin layer ablation or by means of thin layer application or by applying a film.

Figure list

• 1 in einer Seitenansicht in schematischer Darstellung eine Radar- und Lichtausstrahlungsanordnung gemäß einem Ausführungsbeispiel;
• 2 in einer perspektivischen Ansicht in schematischer Darstellung einen Radarreflektor und Radarantenneneinheiten einer Radar- und Lichtausstrahlungsanordnung gemäß einem Ausführungsbeispiel;
• 3 in einer Draufsicht in schematischer Darstellung eine Radardurchlassstruktur einer Radar- und Lichtausstrahlungsanordnung gemäß einem Ausführungsbeispiel; und
• 4 in einer Seitenansicht in schematischer Darstellung eine Radar- und Lichtausstrahlungsanordnung gemäß einem Ausführungsbeispiel.

The invention is described in more detail in the following drawing figures, reference being made to the other drawing figures for reference signs which are not explicitly described in a respective drawing figure. Show it:

• 1 a side view in a schematic representation of a radar and light emission arrangement according to an embodiment;
• 2nd a perspective view in a schematic representation of a radar reflector and radar antenna units of a radar and light emission arrangement according to an embodiment;
• 3rd a plan view in a schematic representation of a radar transmission structure of a radar and light emission arrangement according to an embodiment; and
• 4th a side view in a schematic representation of a radar and light emission arrangement according to an embodiment.

DETAILED DESCRIPTION OF THE FIGURES

In 1 is a spotlight 1 shown who is a light source 2nd (optionally also projection lens) and a light reflector 3rd and a light-transparent headlight cover 4th with an outer surface 4.1 and an inner surface 4.2 having. The light source 2nd and the light reflector 3rd are like this along an optical axis 7 (Main orientation) aligned that the light in a cone of light 9 through the Headlight cover 4th is emitted. This results in a light propagation path 6 , which starts from the light source 2nd runs frontally to the front and is limited laterally by the specifications of the light reflector. According to a variant, the light propagation path is 6 a cone of light.

In the headlights 1 is a radar module 11 integrated so that a radar and light emission arrangement 10th is formed. At the top 11.1 of the radar module 11 is at least one radar antenna unit 12th (Sending and receiving unit) provided. Above the radar module 11 is a radar reflector 13 arranged. The headlight cover 4th has at least one light-transparent, frequency-selective radar transmission structure 14 on, in particular in the form of a coating. In particular, an external radar transmission structure 14.1 and / or an internal radar transmission structure 14.2 be provided.

Between the radar module 11 and the radar reflector 13 is an intermediate level 15 provided with a radiation-effective cover. The intermediate level 15 or the cover falls at least approximately with the light reflector 3rd bottom tangent plane 18th (Tangential plane) together, and / or is aligned at least approximately parallel to it. The optical axis 16 of the radar module or the respective antenna unit 12th is at least approximately orthogonal to the intermediate plane 15 aligned, and / or is at least approximately vertically aligned.

A headlight cavity spanned by the headlight cover and optionally also spanned by the light reflector 17th serves to accommodate all radar technology components. Here is the radar module 12th together with the antenna unit 13 in a partial cavity covered by the headlight cover and the radar reflector 17.1 (especially in the form of a gable roof) in an area at the very front of the headlight cavity 17th adjacent to the headlight cover 4th arranged. The partial cavity becomes frontal 17.1 from the headlight cover 4th limited, and the partial cavity is at the rear (rear) 17.1 from the radar reflector 11 limited.

In a contact point or an attachment point 13.5 of the radar reflector for contact with the headlight cover, an angle is formed between the headlight cover and the radar reflector, which angle is in particular in the range from 45 to 90 °, for example approximately 55 to 60 °. This contact angle can also be described as a roof angle between two oppositely inclined (roof) surfaces, in particular with reference to a gable roof construction. Further contact points with further angles can also be formed between the headlamp cover and the radar reflector, in particular, if the radar reflector is optionally three-dimensional, also at the interface to the headlamp cover.

The beam path 19th that of the radar module 12th emitted, propagating radar radiation or RF wave initially runs transversely to the direction of emission x , in particular at least approximately orthogonal to it and / or at least approximately in the vertical direction, and is then by means of the radar reflector 13 deflected by approximately 90 °, by means of the radar reflector and / or by means of a respective radar transmission structure 13 , 14 a detection area 8th is defined. Out 2nd shows that the detection area can optionally or additionally also be arranged laterally, in particular in the case of a radar reflector with a three-dimensional extension.

The arrow x in 1 indicates the radiation direction (emission direction) or the corresponding longitudinal position of a respective component in the radiation direction, the respective longitudinal position being detected, for example, starting from the light source. The radar module and the radar reflector and optionally also the antenna unit are in at least approximately the same longitudinal position x arranged. The headlight cover 4th extends rearwards (backwards) into a longitudinal position smaller than the longitudinal position of the radar module and the radar reflector. In other words, the headlamp cover not only overlaps the radar module and the radar reflector, but also completely covers these two components in the direction of radiation.

In 2nd is a radar and light emitting device 10th shown which a plurality of radar reflectors and a plurality of radar antenna units 12th , 12a has, namely at least one radar antenna unit 12a for inclined radiation, and which is set up for lateral detection. In addition to the radar reflector previously described 13 is also a radar reflector 13a set up for oblique radiation and a radar reflector 13b set up for lateral irradiation (side view). All three types of radar reflectors can be provided together in a modular manner as a uniform radar reflector, in particular by using each radar reflector as a reflector element 13.4 is provided with two-dimensional extension. Every reflector element 13.4 can be characterized by at least one of the following components: first (in particular one-sided) frequency-selective structure 13.1 (Radar transmission structure), second (in particular one-sided) frequency-selective structure 13.2 , each introduced in particular as a coating or integrated into the material; and / or light-transparent, electrically conductive oxide layer (TCO) 13.3 , either one-sided or two-sided. Optionally, only a single frequency-selective structure is provided, in particular integrated into the material of the respective reflector element 13.4 . The TCO layer 13.3 can alternatively or additionally also on the headlight cover 4th be trained.

In 3rd is a single embodiment of a radar transmission structure 14 shown in detail. The radar transmission structure 14 is formed by a system of at least four types of structures, in particular a first frequency-selective radar transmission structure 14a , in particular the so-called bandpass structure, and a second frequency-selective radar transmission structure 14b , in particular the so-called Fresnel range, and a third frequency-selective radar transmission structure 14c , in particular so-called PRS (partially reflective structure), and a fourth frequency-selective radar transmission structure 14d , in particular the so-called lowpass structure. The respective structure can be introduced or integrated in particular by a laser process. Optionally, one or more transparent, electrically conductive oxide layers (TCO) can be used for a single or for each radar transmission structure. 14.3 be provided, in particular for the purpose of optimizing the reflection properties.

In 4th is an embodiment of a further radar and light emission arrangement 10th shown in a headlight 1 is integrated. The radar module 11 is arranged behind several light sources 2. The optical axes 7 and 16 lie one above the other or are at least approximately parallel to one another. The light sources 2nd outline the optical axis 16 the antenna unit 12th or are at least partially arranged around it. Between the light sources 2nd and the detection area 8th the (only) the light-transparent, radar radiation-shaping headlight cover is arranged. Between the antenna unit 12th and the light sources is a radar radiation shaping device 14 with TCO layer 14.3 arranged, which according to the arrangement 4th does not necessarily have to be transparent to light.

Reference list

1

Headlights

2nd

Light source or projection lens

3rd

Light reflector

4th

Headlight cover, in particular in the form of or with a light-transparent radar radiation shaping device

4.1

Outer surface

4.2

Inner surface

6

Light propagation path

7

optical axis of the light source or light reflector (main orientation)

8th

Detection range

9

Cone of light

10th

Radar and light emission arrangement

11

Radar module

11.1

Top

12th

Radar antenna unit (transmitter and receiver unit)

12a

Radar antenna unit for inclined radiation

13

light-transparent radar radiation shaping device, in particular radar reflector

13.1

first frequency-selective structure, in particular coating or integrated

13.2

second frequency-selective structure, in particular coating or integrated

13a

Radar reflector or radar reflector element for oblique radiation

13b

Radar reflector or radar reflector element for lateral radiation (side view)

13.3

light-transparent, electrically conductive oxide layer (TCO)

13.4

Reflector element, in particular with two-dimensional extension

13.5

Contact point or attachment point for headlight cover

14

Light-transparent radar radiation shaping device, in particular frequency-selective radar transmission structure, in particular in the form of a coating and / or integrated into the material

14.1

external radar transmission structure, especially as an outer coating

14.2

internal radar transmission structure, especially as an inner coating

14.3

transparent, electrically conductive oxide layer (TCO)

14a

first frequency-selective radar transmission structure, in particular bandpass

14b

second frequency-selective radar transmission structure, in particular Fresnel range

14c

third frequency-selective radar transmission structure, in particular PRS

14d

fourth frequency-selective radar transmission structure, in particular lowpass

15

Intermediate level with radiation-effective cover

16

optical axis of the radar module or antenna unit

17th

Headlight cavity, spanned by the headlight cover and optionally also spanned by the light reflector

17.1

covered partial cavity

18th

tangent plane (tangential plane), especially aligned as a horizontal plane

19th

Beam path (emitted, propagating radar radiation or RF wave)

x

Emission direction (emission direction) or longitudinal position

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• US 2008/0158045 A1 [0004]
• US 2011/0279304 A1 [0005]

Claims (12)

Radar and light emission arrangement (10), in particular for vehicles, set up for emitting light and radar radiation and set up for detecting at least reflected radar radiation, comprising: a headlight (1) with a light-transparent headlight cover (4) and a light source arranged behind the headlight cover ( 2) and a light reflector (3); a radar module (11) with a radar antenna unit (12) arranged behind the headlight cover and integrated into the headlight; characterized in that the radar and light radiation arrangement (10) has at least one radar radiation shaping device (13, 14), in particular a frequency-selective radar radiation shaping device. Radar and light emission arrangement according to Claim 1 , wherein the at least one radar radiation shaping device (13, 14) is arranged in the radiation direction (x) of the radar radiation. Radar and light emission arrangement according to one of the preceding claims, wherein the at least one radar radiation shaping device (13, 14) is arranged in the reflection direction of the radar radiation. Radar and light emission arrangement according to one of the preceding claims, wherein the at least one radar radiation shaping device (13, 14) is flat, in particular planar or curved. Radar and light emission arrangement according to one of the preceding claims, wherein the at least one radar radiation shaping device (13, 14) is frequency-selective, in particular in that the radar radiation shaping device comprises a frequency-selective radar transmission structure (13.1, 13.2, 14.1, 14.2); and / or wherein the at least one radar radiation shaping device (13, 14) is arranged in the emission direction of the light source (2). Radar and light radiation arrangement according to one of the preceding claims, wherein at least one radar radiation shaping device (13, 14) is provided on the at least one radar radiation shaping device, each with an individual radar radiation shaping function. Radar and light emission arrangement according to the preceding claim, wherein the at least two radar radiation-shaping regions are arranged / formed in the same radar radiation-shaping device. Radar and light emission arrangement according to one of the preceding claims, wherein the radar and light emission arrangement (10) has a radar reflector (13) arranged behind the headlight cover (4) integrated in the headlight, and wherein the radar module (11) is arranged below the radar reflector; and / or wherein the radar reflector together with the radar module is arranged at least approximately in the same longitudinal position (x), in particular completely overlapped or covered by the headlight cover (4), in particular in a last third of the longitudinal extent of the radar and light emission arrangement (10) in the direction of radiation. up to the headlight cover; and / or wherein the radar reflector (13) is arranged below an optical axis (7) or an axis corresponding to the main orientation of the light reflector (3) or the light source (2); and / or wherein a / the beam path (19) of the radar radiation is deflected by means of the radar reflector (13) in the range from 70 to 110 °, in particular in the range of 90 °, in particular at least approximately in the direction of emission (x) of the radar and light emission arrangement is aligned; and / or wherein the radar reflector (13), in particular the inside thereof, is arranged with an inclination in the range of 35 to 60 °, in particular 40 to 50 °, relative to the direction of emission (x) or relative to the horizontal, at least in sections; and / or wherein the radar reflector (13) is arranged relative to the headlamp cover (4) such that the radar reflector and the headlamp cover form a roof structure covering the radar module (11) with the geometry of a gable roof with two oppositely inclined surfaces, in particular with an included angle in the range of 45 to 90 °; and / or wherein the arrangement and / or orientation of the radar reflector (13) is motor-adjustable; and / or wherein the radar reflector (13) has a three-dimensional extension at least in sections and is set up to also laterally reflect radar radiation; and / or wherein the radar reflector (13) consists of substrate material which is transparent to light and radar radiation and has a further device which forms radar radiation, in particular in the form of a coating or as an electrically conductive surface; and / or wherein the radar reflector (13) has a further radar radiation shaping device and is arranged relative to the headlight cover (4) such that the radar radiation from the radar module (11) to outside of the headlight cover (4) at least twice a frequency-selective radar transmission structure (13, 14 ) shines through; and / or wherein the radar reflector (13) has a light-transparent, electrically conductive oxide layer (13.3) or an electrically conductive surface on at least one of its surfaces. Radar and light emission arrangement according to one of the preceding claims, wherein / the radar radiation shaping device (13, 14) has at least in sections a periodic arrangement of structural patterns, with the structural patterns in particular in a concentric arrangement; and / or wherein a / the radar radiation shaping device (13, 14) is designed as a coating or as a film or as an electrically conductive surface; and / or wherein the headlight cover (4) forms a substrate for the radar radiation shaping device (13, 14); and / or wherein / the radar radiation shaping device has a conductive part in the form of a light-transparent, electrically conductive oxide layer (13.3, 14.3). Use of a radar and light emission arrangement, in particular a radar and light emission arrangement (10) according to one of the preceding device claims, for emitting light and for frequency-selective emission of radar radiation and for specifying a radar detection area (8) by means of at least one, in particular by means of at least two Radar radiation shaping devices, in particular frequency-selective radar transmission structures (13, 14), which is also provided at least in or on at least one side of a light-transparent headlight cover (4) of the radar and light emission arrangement, in particular in the beam path (19) starting from a radar module (11) in series one after the other in at least two positions comprising a position on a radar reflector (13) arranged outside the light cone of the light source, in particular in a headlight (1) of a vehicle, the radar module (11) outside one of the light source emi tted light cone, in particular below the at least one, in particular below, the at least two radar radiation-shaping devices (13, 14), with an upward, in particular at least approximately orthogonal to the optical axis (7) of a light source of the headlight, oriented optical axis ( 16) of the radar module. Radar and light emission arrangement (10) for vehicles and set up for emitting light and radar radiation and set up for detecting at least reflected radar radiation, with a headlight (1) with a light-transparent headlight cover (4) and a light source (2) arranged behind the headlight cover a light reflector (3), and with a radar module (11) arranged behind the headlight cover and integrated in the headlight with a radar antenna unit (12), in particular radar and light emission arrangement (10) according to one of the preceding device claims, produced by forming at least one radar radiation shaping device, in particular in the form of a frequency-selective radar transmission structure (13, 14), at least also on or in the headlight cover (4), the radar radiation-shaping device comprising a conductive part in the form of a light-transparent, electrically conductive oxide layer t (13.3, 14.3) or is at least partially formed thereby, and wherein a structure pattern is introduced into the radar radiation shaping device by thin-layer removal, in particular by means of a laser. Radar and light emission arrangement according to the preceding claim, wherein a structural pattern is introduced into the radar radiation-shaping device by thin-layer removal or thin-layer application, or wherein the radar radiation-shaping device is produced by means of thin-layer removal or by means of thin-layer application or by applying a film.

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